Speed responsive device



April 12, 1938. H BONE 2,113,645

SPEED RESPONSIVE DEVICE Filed March 20, 1955' 4 Sheets-Sheet l 59 ll 7 I III:

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56 /1136 I 59 N-ziai 45 MENTOR MEI-IV v F 5 HerbemLBozze.

HIS ATTORNEY H. L. BONE April 12, 1938.

SPEED RESPONSIVE DEVICE Filed March 20, 1935 4 Sheets-Sheet 2 INVENTOR Herbert L.B0120. P Q14 HIS ATTORNEY April 12, 1938. H. L. BONE 2,113,645

' SPEED RESPONSIVE DEVICE Filed March 20, 1955 4 Sheets-Sheet 5 INVENTOR 4H 164 m bert L.B012e.

Mi 9.8. 59% BY M 26 HIS ATTORNEY April 12, 1938. BONE 2,113,645

' SPEED RESPONSIVE DEVICE;

Filed March 20, 1955 4 Sheets-Sheet 4 Fl 9. 12. Pain Control Belay 12 125 5 Governor 7 Low Speed 32 o 5 5 Governor 109 I Cuzouz J11 INVENTOR Swdeb HePbePzL Bone.

Fig. BY 6L2, 11M

HIS ATTORNEY Patented Apr. 12, 1938 UNITED STATES PATENT OFFICE srnen nnsronsrve DEVICE Application March 20, 1935, Serial No. 12,002

11 Claims.

My invention relates to speed responsive devices.

I will describe several forms of apparatus embodying my invention, and will then point out the novel features thereof in claims.

An object of my invention is the provision of a novel and improved speed responsive device which is highly sensitive at a predetermined critical speed during both acceleration and deceleration, and wherewith movement of the governor parts occurs only at the critical speed, but once their motion has started a complete movement of the parts from one extreme position to another extreme position without further change in speed is effected. Another object of my invention is the provision of a speed responsive device of the type herein involved which is balanced against movement due to vibration or shocks. Still another object of my invention is the provision of a speed responsive device which is essentially a plurality of governors compactly mounted together, with each such governor efiective to register an independent predetermined speed. Independent governors for registering different speeds permit each governor to be provided with characteristics, best suited for the specific speed it is to register. Other objects and advantages of my invention will appear as the specification progresses.

For a better understanding of my invention reference may be had to the accompanying drawings wherein speed responsive devices particularly adapted to railway trains are disclosed. It is to be understood, however, that I do not wish to limit my invention to any specific application and the application to railway trains is by way of illustrating the many places my invention is useful.

In the accompanying drawings, Fig. 1 is a vertical view partly in section of one form of a speed responsive device embodying my invention and which is operatively connected with the axle of a vehicle of a railway train. Fig. 2 is a plan view 01 the governor head of the speed responsive device of Fig. 1 and showing the inertia and contact parts thereof. Fig. 3 is a side view of the device of Fig. 1 with the cover of the governor chamber removed and certain of the parts broken away to show the cut-out mechanism. Fig. 4 is a plan view of the device of Fig. 1 with the cover of the governor chamber and the governor head both removed, to show the cut-out contact mechanism and the contact brush holders. Fig. 5

'is a view partly in section showing an alternative driving mechanism for the speed responsive device of Fig. 1, and Fig. 6 is a view taken on the line VIVI of Fig. 5. Figs. 7 and 8 are plan and side views, respectively, of a second form of governor head which may be applied to the device of Fig. 1 and which when so applied constitutes a second form of speed responsive device em- 5 bodying my invention. Fig. 9 is a plan view with certain of the parts broken away of a third form of governor head which may be applied to the device of Fig. 1 and which when so applied constitutes another embodiment of my invention. 10 Fig. 10 is a view partly in section taken from the left-hand side of Fig. 9, and Fig. 11 is a sectional view on the line )H--XI of Fig. 9-. 12 is an enlarged detail view showing the spring ad justment member for the restraining spring of 15 Fig. 9. Fig. 13 is a diagrammatic view of a control circuit and control mechanism for governing the speed of a railway train by the speed responsive devices illustrated in Figs. 1 to 12.

Referring first to Fig. 1, an axle extension plate I is bolted to the end of an axle 2 of a vehicle of a railway train by means of tap bolts 3, and is centered and solidly keyed to the axle 2 by means of a dowel pin 4 which fits into the axle center, and by a bar-shaped lug 4 which fits into a slot in the end of the axle. To look the usual bearing nut 5 for the axle '2, a sheet metal washer 6 is provided, the washer B'being so designed that portions of it can be bent down into the usual locking slots provided in the face of the bearing nut 5, the portions to be bent down being so spaced that the nut 5 can be moved in small steps. A shaft portion 1 is formed integral on the axle extension plate I and projects through a separating plate 8 which plate is secured to a main casting 30 by tap bolts such as shown at 52. The main casting 30 is secured to the axle bearing housing of the vehicle axle 2 in any convenient manner not shown. This casting 30 forms a casing having two chambers, a gear 4g chamber I96 and a governor head chamber 31, the gear chamber I96 being provided with an inspection plate I91 and an oil filler plug I98 (see Fig. 3) and the governor head chamber 31 being provided with a dirt proof cover Hill. The plate 8 is provided with a felt oil seal washer ill to prevent creepage of oil. As an additional means to prevent transfer of oil between the driving portion of the speed responsive device and the bearing of the axle 2, an oil deflecting plate H, which is a thin metal disk, is also carried on the shaft portion 1. Suitable shims I! are provided behind the oil deflecting plate It so that a bevel gear l3, which is keyed and bolted to the shaft 1, can be properly positioned with respect to a mating bevel gear l4. The driven gear I4 is cut on a tubular shaft l3 which extends from a point some little distance below the back of the gear l4, upward to the inner race of an upper ball bearing I3. The inner surface of the tubular shaft I3 is provided with splines near its lower end which mate with splines l3 cut on a spindle l3. The tubular shaft I3 is also provided with a shifting plate 23, the purpose of which will be explained later. The driven gear i4 is held in its upper position by a spring 2| which presses against the back of the gear and rests in a cup 22, and the lower face of the cup 22 in turn rests against the inner race of a lower ball bearing 23, the ball bearing 23 being held from slipping off the spindle is by a collar 24 formed on the end of the spindle l3.

The outer race of the upper ball bearing I3 is held in a bearing retainer 23. which fits into a machined pocket 23 in the main casting 33. The bearing retainer 23 is held in place by means of a large nut 3i which is provided with clearance so that the outer race of the bearing I3 is not clamped although the bearing retainer 23 is clamped solidly. The nut 3| (see Fig. 4) is provided with locking slots 32 adapted to receive the lock members 33 of a lock washer 33, and which washer is in turn secured in position by tap bolts 34 screwed into the main casting 33. Locking wires 33 may be threaded through holes of the tap bolts 34 if desired. The nut 3| is provided with an oil seal 33 which prevents creepage of oil from the gear chamber I33 into the governor head chamber 31. The inner race of the bearing i3 is held in place against the upper end of the tubular shaft |3 by the hub 23 of a collector ring drum 23 which drum is keyed to the spindle I! at 34 and is drawn down by means of a nut 21 on a threaded portion of the spindle l3. The outer race of the lower ball bearing 23 fits into a machined pocket 23| in the main casting 33. Inasmuch as the lower ball bearing 23 is held in position by the collar 24 on the lower end of the spindle i9 and the hub 23 of the collector ring drum 23 is held in position against the upper surface of the inner race of the bearing |3, all the forces set up by the spring 2| are taken up in the tubular shaft l3 itself. The only thrust transmitted through the shaft i3 is that resulting from the endwise thrust of the gear l4 and the weights of the gear i4 and shaft l3. This thrust as well as the weights of the spindle IS, the collector ring drum 23 and a governor head mounted thereon as will be shortly described are carried on the upper ball bearing 3 since the lower bearing 23 is free to move endwise in its pocket 23| as will be understood by an inspection of Fig. 1, and can carry no thrust. Hence the spindle I3 is accurately journaled in the main casting 33 in a vertical position, and the gear l4 mounted on the spindle I3 is held in mesh with the gear |3 secured to the train axle 2 with the result that the spindle I3 and collector ring drum 23 are normally rotated at a speed corresponding to the speed of the train, the thrust and weight of this drive mechanism being carried on the upper ball bearing l3. As will appear hereinafter, the tubular shaft I3 is at times depressed and the gear i4 lowered out of mesh with the gear l3 with the result that the spindle l3 and drum 23 are not then driven by the train axle 2.

The bearing (not shown) for the train axle 2 may be of the usual self-aligning type which type permits movement of the axle 2 about the center of the spherical surface of the bearing, and thus gear |3 moves upward, the gear teeth are made' as large as possible; and to prevent breakage of the gear teeth when the gear |3 moves downward, the spring 2| is so proportioned and adjusted that before 'sufllcient force to break the teeth is obtained, the spring is compressed.

A governor head 33, a brush assembly, a terminal board and a cut-out contact mechanism are mounted in the governor chamber 31 together with the collector ring drum 23, and these several devices will now be described in the order named. The governor head 33 consists of an insulation ring 4| having a skirt 242, two collectors rings 33 and 43 and a governor plate 43 on the latter of which are mounted inertia and contact members. The collector rings 33 and 43 are molded into the skirt portion 242 of the insulation ring 4| which in turn is molded onto the drum 23 and is fixed in place on the drum by an annular lug 42. The governor plate 43 is secured to the upper surface of the insulation ring 4| in any convenient manner not shown, and is held in place by an annular lug 33. In addition to carrying the inertia and contact members, the governor plate 43 has its outer circumferential surface 33 adapted to serve as a collector ring for a common circuit connection as will subsequently be explained. Consequently, the collector rings 33 and 43. and the governor plate 43 are insulated from each other and from the rest of the mechanism and all three are rotated with the spindle l3.

As set forth hereinbefore, the governor plate 43 carries inertia and contact members and as shown in Fig. 2, it is provided with four bearings 44, 43, 43 and 41, and two step supports 43 and 43. As here shown, the four bearings 44, 43, 43 and 41 are positioned on the plate 43 one at each corner of a rectangle the center of which is the center of the plate. The two stop supports 43 and 43 are positioned adjacent opposite sides of the rectangle and each stop support is drilled and tapped to receive two stop screws 33 and 3|. Each bearing 44, 43, 43 and 41 is provided with a bushing, the four bushingsbeing indicated by the reference characters 44', 43", 43 and 41', respectively. Each bushing has mounted therein a pivot pin 31 (see Fig. 3) which in turn carries an inertia member in the form of a bell crank, one of whose arms serves as a contact arm and the other arm of which is provided with a governor weight, the contact arm being disposed approximately at right angles to a center line between the center of the weight and the pivot pin. These four inertia members 33, 33, 33 and 3| are arranged in two pairs, the members 33 and 33 constituting what I shall term a low speed pair and the members 33 and 3| constituting what I shall term a high speed pair. In other words, the inertia members 33 and 33 form a low speed governor, and the inertia members 63 and 3| form a high speed governor. To clarify the following description I shall refer to the inertia members 33 and 33 as a low speed governor effective to register a speed which corresponds to a speed of twenty miles per hour for the railway train of which the axle 2 is a part, and I shall refer to the inertia members 33 and 3| as a high speed governor effective to register a speed corresponding to a speed of seventy-two miles per hour for the railway train. It is to be understood, of course, that my invention is in no way limited to these specific speeds and they are used by way of illustration o'nly. Each of the low speed inertia members 58 and 59 is provided with a relatively large governor weight consisting d two portions disposed one above the other, the two portions of the weight of the member 58 being identified by the reference characters 58 and 58 and the two portions of the weight of the member 59 being identified by the reference characters 59 and 59 The two high speed inertia members 60 and 5| are each provided with a single governor weight of relatively small size and which Weights are designated by the reference characters 68- and BI, respectively. As shown more clearly in Fig. 1, the arrangement of the governor weightsis such that the weight 89- of the high speed inertia member 68 swings between the two weight portions 58 and 58 of the low speed inertia member 58, and the weight 6| of the member 8| swings between the two weight portions 59 and 5930f the low speed inertia member 59. The contact arm 82 of the low speed inertia member 58 is made straight but the contact arm 63 of the other low speed in ertia member 59 is forked to fit over the straight portion of the arm 62 and has secured to an outer prong of the fork a contact '18. In like manner the contact arm 64 of the high speed -inertia member 6| is made straight but the contact arm 65 of the mating inertia member 60 is forked to fit over the straight portion of the arm 54 and has secured to an outer prong of the fork a contact 82. v w

The low and high speed governors are each restrained in theii movement by a spring member and each has its movement limited by stops. For example, the low speed inertia members 58 and 59 are restrained from rotation about their pivot pins by means of a spring 65 one end of which is hooked to an adjusting screw 61 in the member 58 and the other end of which is hooked to an adjusting screw 68 in the member 59. In a similarmanner the high speedv inertia members Bland 5| are restrained from rotation about their pivot pins by a spring 69 which has its two ends hooked to the adjusting screws I and H in the members 68 and 6|, respectively. The outward motion of the weights of the members 58 and 59 is limited by the stop screws 50, and the outward motion of the weights of the high speed members 68 and is limited by the stop screws 5|. The

. motion of the low speed inertia members 58 and and BI to draw their weights toward the center of the plate 43 is limited by a contact post 73 which cooperates with the contact arms 64 and 65 of the high speed inertia members. The parts are so proportioned that at zero speed of rotation of the governor plate 43 the restraining spring 66 is effective to draw the weights of the low speed governor inward toward the plate center, the inward movement being limited by the contact post 12, but that rotation of the governor plate 43 causes a centrifugal force of the weights which force at some critical speed is effective to overcome the force of the restraining spring 66 and the weights moved outward from the plate center, the outward movement being limited by the stop screws 50. The speed of rotation of the governor plate 43 at which movement of the low speed governor parts occurs is in this instance the speed of rotation which corresponds to the speed of twenty miles per hour for the railway train. Again, the restraining spring 69 is effective at zero speed of the governor plate 43 to draw the weights of the high speed governor inward, the inward movement being limited by the contact post 13, but that-rotation of the plate 43 causes a centrifugal-force of the weights of the high speed inertia members which force at some critical speed is effective to overcome the force of the restraining spring 69 and the weights moved outward until they engage the stop screws 5|. The critical speed of the plate 43 at which movement of the high speed governor parts occurs is in this instance the speed of rotation which corresponds to a speed of seventy-two miles per hour for the railway train.

The low speed governor and the high speed governor each effects a control through the medium of two contacts one. of which is operated by the contact arms of the respective governor and the other of which is stationary and is carried on the associated contact posts 12 or 13 as the case may be. These two contact posts '52 and 13 are rectangular metal bars each of which extends through an opening in the governor plate 43 and is fastened in the insulation ring 46. The posts 12 and 73 are electrically connected to the collector rings 39 and 48, respectively, by means of flexible leads (not shown) which pass through holes drilled in the insulation ring 4|, each lead being secured to the associate contact post and collector ring by terminal screws, or soldered as desired. A contact support '14 is secured to the contact post i2 by means of the screw I5 and this support has fastened to it at one end a spring contact finger l8 which finger has mounted thereon a contact 79 for engagement with the contact 18 secured to the outer prong of the fork of the contact arm 8 of the low speed governor. The end of the support 14 opposite that on which the spring contact finger I5 is secured is shaped to form a stop 83 for the con tact finger as will be understood by an inspection of Fig. 2. It follows that with the contact arm 63 in the position illustrated in Fig. 2 and the contacts 19 and 18 are in engagement, a circuit connection is completed between the collector ring 39 and the governor plate 43, but that when the arm 63 is moved andthe contact 18 breaks engagement with the stationary contact 19 the circuit connection between the collector ring 39 and the plate 43 is broken, this circuit connection including the flexible lead, post 12, support 14, contact finger 16, contacts 18 and 19, contact arms 52 and 63, and a flexible lead (not shown) bridging the metal parts of the bearings 44 and 45. In like manner the contact post 13 has secured thereon a contact support 1? on one end of which is fastened a spring contact finger 80 having a contact 8| adapted to engage the contact 82 secured to the outer prong of the fork of the contact arm 84 of the high speed governor. The opposite end of the support 71 is shaped to form a stop 84 for the spring contact finger 88. Hence, at such time as the contacts 8| and 82 make engagement, a circuit connection is completed between the collector ring 49 and the governor plate 43, but that when movement of the arm 84 takes place to break. engagement between the movable contact 32 and the stationary contact 8| this circuit connection between the ring 40 and the plate 43 is broken, this circuit connection including the flexible lead, post I3, support 11, contact finger 88, contacts 8| and 82,

contact arms 44 and it, and a flexible lead (not shown) bridging the metal parts of the bearings 46 and 41. The manner of utilizing these contacts 18-10 and "-82 of the two governors for accomplishing a desired control will be explained hereinafter.

The governor head 38 constructed in the manner described provides that vibration forces tending to move the head do not change the position of the governor weights with respect to the axis. For example, the weights of the low speed inertia members 58 and 58 are on opposite sides of the center of the governor plate 43 and. are interlocked by means of the contact arms 82 and 63,

' wise shocks.

so that the weight of one member cannot move with respect to the center of the plate unless the weight of the other member moves with it. Thus the only forces eflective to move the weights are those tending to move the weights of both the inertia members 58 and 58 toward the center of the plate or away from the center. Any force tending to move the weights of the members and 59 in the same direction with respect to the center (except radially outward or inward) such as a violent sidewise motion of the 'vehicle axle 2, sets'up equal and opposite turning movements about the pivot pins of the members 58 and 59 which movements belance out at the point where the arms 62 and 63 engage with each other and thus cause no movement of the weights except forthe arms 62 and 63 which are made as light as possible. It is clear that the same condition obtains for the high speed inertia members 80 and GI. It follows that both the low and high speed governors as here mounted on the single gov-' ernor plate 43 are each balanced to eliminate the effect of sidewise vibration and sudden side- Theoretically, this balanced arrangement would permit mounting the governor plate 43 with its axis horizontal or in any other position instead of vertical as shown in the form of the invention here described.

The restraining spring 66 is so positioned that as the weights of the inertia members 58 and 59 move outward, which increases the force exerted by the spring, the spring moves closer to the pivot pins decreasing the moment arm. The parts are so proportioned that the resultant torque on the inertia members is substantially constant throughout the travel of the weights. As explained hereinbefore, the ends of the spring 68 are hooked to the adjusting screws 61 and 68 and hence the tension of the spring 66 may be varied. These adjusting screws 81 and 68 are mounted in their respective weight arms at such an angle that adjustment to increase the spring tension also moves the spring away from the pivots, increasing the moment arm, thus providing, within the limits of the space available, a greater increase in torque about the pivots than could be provided by changing the spring tension alone. It is clear that the relationship of the restraining spring 69 with respect to the high speed inertia members 60 and ii is the same as that just explained for thespring 66' and the low speed inertia members 58 and 58 and it is thought to be unnecessary to repeat the description in detail.

The stationary contacts I9 and BI are mounted on the flexible spring contact fingers l6 and 80, respectively, for the following reasons: When either governor is running close to its critical speed, vibration might'cause slight movements of the inertia members if the weight elements are not exactly balanced and such movements might cause momentary opening of the contacts if the stationary contacts were not mounted flexibly enough to permit the movement. The spring contact fingers 16 and Oil are so proportioned and adjusted as to permit such vibration and to maintain a contact pressure of say about one ounce. Furthermore, a slight amount of wiping of the contacts is desirable in order to make the contacts self-cleaning. Since the spring contact fingers l6 and II and the contacts I! and ii carried thereon are rotated along with the governor plate 43, the contact pressure between the contacts l8 and ll of the low speed governor and the contact pressure between the contacts II and 82 of the high speed governor is, in each case. dependent upon two factors, namely, the spring force of the contact finger and the centrifugal force at the critical speed of the respective governor. The effect of the speed is to tend to force the stationary contacts I! and ll outward due to their centrifugal forces. The spring contact fingers and 80 must be strong enough to resist this centrifugal force and in addition provide the contact pressure desired. In practicing my in-' vention I have found it to be desirable to have the spring force of such value that the contact fingers l6 and 80 rest against their respective stops 83 and 04 with zero pressure at the critical speed of the respective governor. For example, at the critical speed of twenty miles per hour at which the low speed governor operates and the contact arm 83 is moved inward to break engagement between the contacts 18 and 19, the force of the spring contact finger It is such that it rests against the stop 83 with substantially zero pressure. At the critical speed of seventy-two miles per hour at which the high speed governor operates and its contact arm 84 is moved inward to break engagement between the contacts II and 82 the spring contact finger l0 rests against the stop 84 with substantially zero pressure. To accomplish these desirable operating conditions for the stationary contacts of the two governors the respective contact fingers l8 and 80 are proportioned and adjusted as follows: The initial pressure of the contact spring fingers I8 and 80 against their respective stops l3 and 84 at zero speed of the governor plate 43 and with the associated contact arm moved back to open the contact is in each case such that at the speed of the governor plate corresponding to the critical speed of the respective governor and with the contact open, the centrifugal force caused by the weights of the stationary contact and of the contact finger effectively reduces the pressure between the contact finger and its stop to zero but does not move the finger away from the stop. The rate of each spring contact finger is so proportioned that at the critical speed of the respective governor the change in the spring pressure caused by moving the stationary contact the distance between the point where the spring contact finger is against the contact post and where the finger engages the stop is less than the change in the force exerted by the movable contact when moved the same distance due to the governor weights increasing their distance from the center of the governor plate. Consequently, at zero speed of the governor plate 43 the restraining spring of each governor is efiective to draw the governor weights in toward the center of the plate and to swing the contact arms outward with the movable contact in engagement with the stationary contact, the spring contact finger being forced back against its contact ,post with a predetermined initial contact pressure between the movable and stationary contacts.

The force of the restraining spring is, however, opposed by the force exerted by the spring contact finger.

With the restraining spring positioned to exert substantially constant torque on the inertia members throughout the travel of the governor weights and the parts proportioned to provide the contact pressures just explained, the resultant force due to the centrifugal forces on the governor weights and on the stationary contact, and the forces of the restraining spring and the spring contact finger, insure that, when the weights of either governor start to move outward, they immediately move to their extreme outer position without hesitation at any point in their travel. The initial force of the restraining spring of each governor is made sumcient that no movement of the inertia members occurs until the critical speed of the respective governor is reached. However, as the critical speed of the governor is reached and the governor weights start to move outward and the contact arms start to move inward, the stationary contact follows the movable contact until the spring contact finger reaches its stop, and at this point the movable contact and the stationary contact still engage with a pressure sufilcient to insure a reliable circuit connection therethrough notwithstanding vibration movements as explained hereinbefore. As the critical speed of either governor is reached and its inertia members start to move, their movement increases the centrifugal forces of the weights whereas the force of the restraining spring remains substantially constant so that the resultant force causes an outward movement of the governor weights even though there is no further increase in the speed of the governor plate, the weights then remaining against their outward stop for all speeds above the critical speed. This operation of the governor parts is obtained by the structure described during an accelerating operation of the governor plate since the torque exerted by the restraining spring. remains substantially constant, and due to the fact that the centrifugal forces exerted by the weights increase in direct proportion to increase in the radial distance of the weights from the axis of the governor plate, and also due to the fact that the force of the spring contact finger is in opposition to the force of the restraining spring. During deceleration, the weights being in their extreme outward position, they do not move in until their centrifugal forces become less than the force of the restraining spring. Due to their increased distance from thegovernor plate center, the speed at which the weights start to move inward is something less than the speed at which they move outward, but once the movement inward has started, the weights immediately move to their extreme inner position since the force of the spring remains constant whereas the centrifugal forces decrease in direct proportion to the decrease in the radial distance of the weights from the plate center. I have found that with speed responsive devices constructed in the manner described both the low speed governor and the high speed governor operate during deceleration at speeds substantially within four per cent of the speeds at which they operate during acceleration. Hence, both the low speed and the high speed governors are of the unstable class since each provides a restraining force effective to cause its inertia members to occupy one extreme position at all speeds below a respective critical speed and then provides a resultant force effective to move the inertia members to their other extreme position at the critical speed without further increase in the speed, this resultant force being also effective to hold the inertia members in this second extreme position at all speeds above the critical speed. During deceleration the resultant force at substantially the critical speed becomes eiiective to cause the inertia members to move from the outer extreme position back to the inner extreme position.

The brush assembly and the terminal board will now be escribed. Referring to Figs. 3 and 4, the conta brushes 80 and 81 engage the collector rings 89 and 40, respectively, and a third contact brush 88 engages the circumferential surface 56 of the governor plate 43. These three brushes 86, 81 and 88 are preferably of the usual carbon type and are held in the brush holders 89, 90 and 9|, respectively, which holders are held on a terminal board 92 by terminal posts 95, 96 and 91, respectively, the arrangement being such that electrical connection is provided between each terminal post and its respective contact brush. The terminal board 92 is held between two studs 93 which are rigidly fastened in the main casting 30. The studs 93 are provided with tapped holes at their upper ends and by means of tap bolts H8, 3, fiat plate 94 is clamped down on the terminal board 92 and the terminal board is firmly held in place. The parts are so arranged that removal of the plate 94 permits the removal of the entire terminal board and brush assembly. The terminal post 91, which is electrically connected with the governor plate 43, is in turn connected with a terminal post III through a pair of spring contacts I09 and H to be referred to later. Wires attached to the terminal posts 95, 96 and III are carried out of the governor head chamber 31 through a rubber hose 98 connected to a strain relief bushing 99 in the main casting 30. It follows that the governor plate 43 is electrically connected with the terminal post III, and the stationary contacts 19 and 8| of the low and high speed governors, respectively, are electrically connected to the respective terminal posts 95 and 96, and the circuit connections are carried thence by wires brought into the governor head chamber through the hose 98.

That the governor head 38 may be disconnected from the driving axle 2 and the circuit connections leading to the governor contacts may be opened under such disconnected condition of the governor head, I provide a disengaging mechanism which is operated through the medium of a handle located outside of the mechanism case. As here shown, a handle IN is secured by means of a bolt I03 to a shaft I02 which is journaled in a bearing in the main casting 30 and the inner end of which terminates in an eccentric I04, the eccentric being in turn adapted to engage the shifting plate 20 on the tubular shaft I5. The arrangement is such that with the handle IOI down as illustrated in Fig. 3, the eccentric I04 is free from the plate 20 and the gears I3 and I4 are in mesh and the governor head 38 is in an operating condition, but that with the handle I 0| lifted one-half turn the eccentric I04 engages the shifting plate 20 to force the tubular shaft I downward against the action of the spring 2|, and the driven gear I4 is disengaged from the driving gear I3 and an inoperative condition of the governor head is established. The flat surface of the eccentric I04 rests firmly on the upper surface of the shifting 6 aliases plate in this disengaged position. The handle III and the eccentric I04 are held in the position corresponding to the engaging position of the gears by means of a steel ball I05 engaging a hemispherical depression in the shaft I02, the ball I00 being forced into position by means of a heavy coil spring I06 located in a tubular cavity III which. is closed at its outer end by a pipe plug I00. A corresponding depression in the shaft I02 is also provided for th disengaging position of the handle IOI.

In order to assure that the electrical circuits are opened when the governor head is disconnected from the driving axle, the movement of the shifting plate 20 is made to operate the spring contact IIO, the arrangement being such that the contact I 00--I I0 is closed when the plate 20 is up and the contact is opened when the plate is forced downward. The contact spring I I0 is operated by a pin II2 of suitable insulating material and which pin is held in a lever Ill, the lever III being in tum'pinned at I to a shaft III. The shaft II! is Journaled in two bearings H0 and II! formed in the main casting 00 and has pinned to it at 0 a forked cam-shaped lever IIO which lever is adapted to be operated by the shifting plate 20. A flat spring I2I held rigid at one end by a tap screw 200 engages the lever III and tends to rotate the lever I I 3 clockwise to force it back against a stop I20. The cam surface of one of the arms of the forked lever IIO engages the lower face of the edge of the shifting plate 20 and is so shaped that downward movement of the plate 20 operates the forked lever II8 counter-clockwise as viewed in Fig. 4 and the lever H0 and pin II2 are moved to the left against the force of the spring I 2I with the result that the contact spring H0 is forced out of engagement with the contact spring I09 and the circuit connection therethrough is broken. When the shifting plate 20 is moved upward, the cam lever III! is operated clockwise by action of the spring I2I and by the second of the arms of the forked lever IIO engaging the top edge of the plate 20 and the pin H2 is moved to the right away from the contact spring H0 and that spring by its own resiliency engages the contact spring. I09 to close the cir cult connection therethrough. Normally the lever II3 would be operated by the spring I2I alone during this later operation, the forked lever being provided as protection in case the spring I2I should break. The parts are so proportioned that, when the shifting plate 20 oocupies its full upward position, the cam surfaces of the forked lever II8 do not touch the plate since the spring I2I engages the lever II! and forces it back against a stop I 20. It follows that with the handle IOI down, the governor head is operatively connected with the axle 2 through the drive mechanism including the gears I2 and I4, and the common circuit contact I00IIO is closed, but that with the handle IOI rotated upward one-half turn, the governor head is disconnected from the axle 2 and the contact I09- II 0 is open, the handle IOI being held in either of its two positions through the medium of the spring I06.

Many places where a speed responsive device embodying my invention may be used will suggest themselves to those skilled in the art. One arrangement whereby the device when mounted on a railway train may be used in connection with a train control system is disclosed in Fig. 13. In Fig. 13, a..relay MR is the train-carri d mastercontrclrelaycfatrainccntrolsystem. The train control system may be any one of severa'i ypesinpresentdayuseandisnotshown for the sake of simplicity since its structure forms no part of my present invention. It Is deemed suillcient for the present application to point out that under clear and high speed trafilc conditions the master relay MB is so enersized that its armature I22 is heldin the righthand position in engagement with a contact I2I, that is, it is held in the position illustrated in Hg. 13. Under restricted and low speed tramc conditions the master relay MB is so energised that the armature I22 is held in the left-hand position in engagement with the contact I2I, that is, it is held in the position opposite that shown in Fig. 13. MV is an eiectropneumatic valve operative when energized to hold an air valve I20 closed and when deenergized to open the valve I20 and connect the trainbrake pipe BPwith the atmosphere through a vent of such characteristics as to produce a brake pipe pressure reduction effective to establish an application of the train brakes in accordance with standard practice. A whistle W may be attached to the valve MV for soundingawsrningsignaiatsuchtimeasthe brake pipe BP is vented to the atmosphere. For controlling the valve MV a circuit is provided which is traced from one terminal 302 of any convenient source of current such as a battery not shown over contact I22-I24 of the relay MR.

wire I20, terminal post 00 of the speed responsive device. contact 0Il2 of the high speed governor of that device, cut-out contact I00--IIO, terminal post III, wire I21, winding of the magnet of valve NW and thence to the opposite terminal 032 of the current source, and the valve MV is energized. It follows that under the clear traflic position of the master relay MR the electropneumatic valve MV is energized and the vent of the brake pipe is blanked for all speeds up to the critical speed of the high speed governor and which speed I have assumed to be seventy-two miles per hour, but that at this critical speed the high speed governor contact 0I02 is opened in the manner explained hereinbefore and the valve MV is deenergized to sound the whistle W and to effect an application of the train brakes. Again, at such time as the master relay MB is held in the restricted traflic position, a circuit is traced from the battery terminal B32 over contact I22I2l of the relay MR, wire I20, terminal post 00 of the speed responsive device, contact 'I0'I0 of the low speed governor of that device, cut-out contact I 00-I I0, terminal post III, wire I21, winding of the magnet valve NV and to the opposite battery terminal C32. Hence, under the restricted tramc position of the master relay MR the magnet valve MV is energized as long as the speed of the train is below the critical speed of the low speed governor and which speed I have assumed to be twenty miles per hour, but that for speeds above this critical speed the low speed governor contact 10-70 is opened and the magnet valve MV is deenergized to sound the whistle W and to eil'ect an application of the train brakes.

A second form of drive mechanism for operating the governor head is shown in Figs. 5 and 6. Referring to Figs. 5 and 6, the train axle 2 is threaded at its outer end to receive a nut III which is normally provided in roller bearing application to secure the inner race of the bearing. The face of the nut I20 is slotted to receive a lock bar I30 which is held in place by tap bolts I 3| screwed into the end 01' the axle 2. At least one of the slots in the face of the nut I29 is finished to receive a driving ball nut I32 of a driving pin I33 which is secured in a crank I34. This crank I34 is provided with a shaft pin I38 to which is keyed a driving gear I3. A separating plate 8, which is carried on the main casting 30 in a manner similar to the separating plate 8 of Fig. 1-, is provided with a hub I35 which is bored to receive two ball bearings I36 and I31, and in which bearings the huh I 39 of the driving gear I3 is journaled. As set forth in connection with Fig. 1, the vehicle axle 2 may be equipped with a self-aligning bearing which permits an up and down motion of the axle. It is clear that with the drive mechanism constructed as shown in Figs. 5 and 6 the driving ball nut I32 may move back and forth in the slot of the nut I29 with the result that the meshing of the driving gear I 3 with its mate is not affected by the up and down motion of the vehicle axle 2. It is to be seen, therefore, that the speed responsive device of Fig. 1 may readily be provided with the drive mechanism of Figs. 5 and 6.

A second form of governor head is shown in Figs. 7 and 8 and in which form the governor weights are mounted on flat springs. In this form of the invention the governor head consists of a governor plate 43", insulation ring 4I and collector rings 39 and 40, and is mounted on the collector ring drum 26 the same as in Fig. 1. The

. ceive an adjusting screw I41 which is adapted to engage the adjustable arm I42 and adjust the tension of the spring I4I. It follows that the governor weight I40 is biased to an initial position bythe spring MI and is capable of movement in a plane parallel to the governor plate. A- contact post I49 extends through an opening I50 in the governor plate and is secured in the insulation ring 4|, the post I49 being in turn electrically connected to the collector ring 33 through the medium of a flexible lead attached to the post and passing through a hole drilled in the insulation H in the manner explained for Fig. i. A contact spring I5i is fastened to the contact post I49 and this contact spring I5! is adapted to make engagement with. a contact F52 mounted on the weight spring MI, the contact spring it! being also provided with stop members I53 and I55 which are secured to the post M9. A stop I55 is mounted on the governor plate for limiting the outward movement of the weight I40. The parts are so proportioned and adjusted that at zero speed of the governor plate 33 the spring I4! biases the weight I40 toward the center of the plate and to a position where the contact I52 engages the contact spring 53 with suflicient force to press that spring against the stop member I53, the final tension on the spring I42 being adjusted through the medium of the screw I41. Hence. in this normal position of the low speed governor of Fig. 7 an electrical connection is completed the speed of twenty miles per hour for the train of which the driving axle 2 is a part, the centrifugal force of the weight I40 overcomes the biasing force of the fiat spring HI and the weight moves outward until it engages the stop I55, the movable contact I52 breaking engagement with the stationary contact I5I which now rests against the stop member I54. The rate of the flat spring I and its adjustment are so proportioned that an unstable" operation of this low speed governor is obtained but at the same time it is rigid enough to support the governor weight without-vibration and chattering of the contacts.

The inertia member for the high speed governor of Fig. '1 consists of a flat spring I51 and a weight I58, the weight I58 being mounted on one end of the spring by means of a bolt I59 and the other end of the spring being secured by means of a bolt I6I to an adjustable arm I60. The arm I 60 is pivotally mounted on the governor plate 43 at I62. A stop post I63 is mountedon the plate and is drilled and tapped to receive an adjusting screw I64 for adjusting the position of the arm I60 and hence adjusting the tension of the weight spring I51. A contact post I65 extends through an opening I66 in the governor plate and is secured in the insulation ring M. This post I65 is electrically connected with the collector ring 40 by a flexible lead in the manner explained and has secured thereon a contact spring I 61 adapted to make engagement with a contact I68 mounted on the weight spring i5'l, the contact spring I61 being also with two stop members I59 and I10. A stop post I1I secured to the governor plate 43 iimits the outward movement of the weight I58. The parts are so proportioned that at zero speed of the governor plate the spring I51 biases the weight I58 toward the center of the governor plate and to a position where the contact I 68 engages the spring contact I61 and forces that spring contact back against the spring member I'iil with a predetermined initial pressure. In this normal position of the high speed governor an electrical connection is completed between the collector ring 40 and the governor plate 33 through the contact ISL-458. When the governor plate is rotated at a speed corresponding to the speed of seventy-two miles per hour of the railway train, the centrifugal force of the weight 2'53 overcomes the bias of the spring It? and the weight moves outward to the stop I It and in which position connection between the contacts iiil and M53 is opened. The rate of the weight spring I5? and its adjustment are so proportioned that unstable operation is obtained but chattering and vibration of the contacts are avoided. It is clear that the governor head disclosed in Figs. 7 and 8 when connected to the drive mechanism of either Fig. l or 5 will operate the control mechanism of Fig. 13 in the same manner as described for governor head of Figs. 1 and 2.

A third term of governor head is disclosed in Figs. 9, l0, l1 l2 and wherein the insulation ring 45,, the collector rings 3E! and 0 and the governor plate 33 are mounted on the collector ring drum the same as in the former cases. In this form of the invention. the bearings M, 35, 46 and 4! are positioned on the governor plate 43 in a manner similar to that of Fig. 2 and an inertia member is pivotally mounted in each bearing, the four inertia members being here identified by the reference characters H2, H3, I14 and I155. The two inertia members H2 and I18 cooperate to form the low speed governor and the two members I14 and Ill cooperate to form the high speed governor. Each of these four inertia members is in the form of a bell crank having a weight arm and a contact arm which are at right angles to each other. The governor weights I18 and I11 of the low speed inertia members I12 and I13, respectively, are each formed in two portions as will be understood by an inspection of Fig. 10. but the weights I18 and I18 of the respective high speed inertia members I14 and I18 are each a single weight of relatively small size and are adapted to swing between the two portions of the weights of the low speed inertia members in the same manner as explained for the governor weights of Figs. 1 and 2. As here shown, each inertia member I12, I13, I14 and I18 is provided with an auxiliary weight which is mounted on an. arm the center line of which is in the same plane as the center line of the contact arm, the contact arm and the auxiliary arm being located, however, on opposite sides of the pivot. For example, the low speed inertia members I12 and I18 are provided with the auxiliary weights I88 and Ill, respectively. In like manner the auxiliary weight I8I of the other low speed inertia member I 13 is positioned opposite the contact arm I84. The high speed inertia members I14 and I15 are provided with the auxiliary weights I88 and I88, respectively. and each of these auxiliary weightsis positioned as to balance the contact arm.

The contact arms I82 and I84 of the low speed governor are interlocked and to that end the arm I82 is formed straight and the arm I84 is formed with a forked end to fit over the arm I82. As here shown, the straight arm I82 has mounted thereon a circuit controlling contact I81 which is adapted to engage the stationary contact 18 mounted on the contact finger 18 secured to the contact post 12, whereas in Fig. 2 the movable contact was mounted on the outer prong of the forked arm. The contact arms I88 and I88 of the high speed governor are interlocked by being arranged with the arm I88 straight and the arm I88 forked to fit the arm I88 and the straight varm I88 is provided with a contact I88 which is adapted to engage with the stationary contact 8| mounted on the contact finger 88 secured to the contact post 18. The stationary contacts 18 and 8| are mounted on spring contact fingers 18 and 88 which themselves are carried on the contact posts 12 and 18in the manner explained for Fig. 2 except for the fact that the contact fingers are shaped to form stops whereas in Fig. 2 the contact supports are shaped to form stops and for the fact that the posts 12 and.18 are here positioned not on the diametrical line of the governor plate which passes through the interlocking point of the contact arms but are located slightly to one side of such a line. It will be understood, of course, that the contact posts 12 and 18 of Fig. 9 are electrically connected through flexible leads with the collector rings 88 and 48 and that the outer surface 88 of the plate 48 is adapted to make engagement with the contact brush 88 the same as in Figs. 1 and 2. It

follows that an electrical connection is completed between the contact brush 88 which engages the collector ring 88 and the brush 88 which engages the outer surface of the governor plate 48 when the contact 18I81 of the low speed governor is closed, but that this circuit connection is opened when the governor is operated to move the contact I81 out of engagement with the stationary contact 18. Also, an electrical connection is completed between the brush 81 which engages the collector ring 48 and the brush 88 which engages the governor plate 48 when the contact 8I.I80 of the high speed governor is closed, but that this connection is opened when the governor is operated to move the contact I88 out of engagement with the stationary contact 8I.

Each inertia member I12, I13, I14 and I18 has formed on its weight arm an L-shaped member for connection with a restraining spring. Referringespeciafly to Figs. 11 and 12, an L- shaped member I 8I is formed on the weight arm of the inertia member I14, and a projection I82 of this member "I is drilled with holes as indicated at I88 of Fig. 12. Each of the other in- "ertia members I12, I13 and I18 has formed thereon a similar L-shaped member to that Just described for the inertia member I14. A restraining spring I88 has one end hooked into one of the holes I83 of the L-shaped member "I on the inertia member I14 and its other end hooked into one of the holes on the L-shaped member of the high speed inertia member I18. 'fhe parts are so proportioned and adjusted that at zero speed of the governor plate 48 the restraining spring I88 is effective to draw the weights of the inertia members I14 and I18 toward the center of the plate 43 and-to move the contact arms- I88 and I88 outward with the contact I88 ment being limited-by the contact post theplate 48 is'rotated at the speed corresponding to a speed of seventy-two miles per hour of the railway train the'c'entrifugal forces of the main governor weights I18 and I18 are effective to overcome the force of the restraining spring I88-and the weights moved outward and the contact 8I--I88 is opened, the movement of the weights being limited by the stop screws 88. Hence. this high speed governor occupies the position to close the contact 8II88 at all speeds of the governor plate below the critical speed but at the critical speed the parts move to their other extreme position and the contact is opened without any further change in the speed of the plate since the torque of the restraining spring I88 remains substantially constant during this movement but the centrifugal forces of. the

weights increase as they move outward from the plate center. It is clear that by changing the holes to which the spring I88 is connected the tension of the spring can be varied and operation of the associated governor adjusted accurately at the predetermined critical speed.

A restraining spring I88 is connected with the low speed inertia members I12 and I13 and this spring functions in a manner similar to that Just explained for the spring I88 except for the fact that the parts are so proportioned that the centrifugal forces of the governor weights I18 and I11 become effective when the plate 43 is rotated at a speed corresponding to the speed of twenty miles per hour of the railway train to overcome the force of the restraining spring I88 and the weights moved outward to open the contact 18I81.

0n the weight arm of the inertia member I14 and located opposite the position of the L-shaped member I8I, a balancing member I84 is formed. This member I84 is so proportioned that its mass balances the mass of the L-shaped member and a better balanced arrangement for the inertia member I14 is obtained thereby. In a like manner each of the other inertia members I12, I13 and I is provided with a balancing member positioned opposite its L shaped member. I have found that with each inertia member constructed in the manner here described, movement of the governor parts during deceleration occurs at a speed very close to the speed at which movement occurs during acceleration, and furthermore with the restraining spring attached to the inertia members in the manner disclosed for this third form a relatively large range of speed regulation ance of the head as a whole.

is obtained without changing any of the parts other than the connection of the spring.

It is clear that with the governor head of Figs. 9, 10, 11 and 12 mounted on the drive mechanism of either Fig. 1 or 5, the control mechanism of Fig. 13 may be operated in the manner previously explained.

From the foregoing description of this third form of governor head it is clear that it is of the unstable type. The headis balanced statically without the weights, and the weights are so proportioned that they .do not cause any unbal- Furthermore, the design of this third form of governor head is such, that, due to its shallowness, the moment arm of a .couple which might be produced due to dynamic unbalance tending to displace the head with respect to its axis of rotation, would be very short so that it probably would have very little effect. The design of the head is such that at any section taken perpendicular to the axis of rotation, the weight on one side of the axis is reasonably well balanced with respect to the weight on the other side. The result of this condition is an inherent dynamic balance if the static balance is correct.

The individual governor weights and inertia members are balanced as follows: Referring to Fig. 9, if a line is drawn between the two pivots of the low speed inertia members I12 and I1! and perpendiculars be drawn to this line at the pivots, the center of gravity of each individual inertia member I12 and I13 lies on the perpendicular line through the respective pivot. It is theoretically desirable that these two perpendiculars on which are located the centers of gravity of the inertia members remain parallel at all times. This, of course, is obviously impossible since the weights I16 and I11 move away from this position in opposite direction during their travel from one extreme position to the other. This movement, however, is slight and does not materially affect the operation.

The position of the center of gravity on this perpendicular line is effected as follows: Looking at the inertia member I12, for example, the perpendicular line is assumed to pass through the center of the governor weight I16 .which constitutes the main mass of the inertia member. The contact arm I 82 is assumed to lie on the line between the two pivots, and it is therefore perpendicular to the aforementioned perpendicular through the weight I16. The contact arm I82 is balanced against the auxiliary weight I80 so that the center of gravity of these two parts lies on the perpendicular line through the weight I16. The L-shaped member I9I holding the spring I99 is balanced by the associated member I 94 so that the center of gravity of these two parts also lies on the perpendicular. The center of gravity of the weight I16 is, of course, at the center, and therefore also on the perpendicular. It now the respective parts of the inertia members I12 and I13 are similar the center of gravity of each inertia member I12 and I11 of the low speed governor lies on the perpendicular through the center of its weight and is the same distance from the center of the pivot.

respective centers of gravity of the individual inertia membershand by simple mechanics it will be apparent that the moments tending to turn these inertia members about their pivots are equal since the parallel lines of the forces due to vibration passing through their centers of gravity are at equal distances from the centers of the pivots and the forces are equal since the weights of the two members are equal. Since the moments are than equal and in the same direction they tend to move one inertia member toward the center of the governor head and the other inertia member away from the governor head center with equal forces. Due to the interlocking connection of the contact arms I82 and I84, it is impossible for the inertia members to move in this manner and the forces tending to produce movement as the result of vibration or shocks are balanced out.

Since the center of gravity of each inertia member I12 and I13 lies a certain distance from its pivot and lies on the perpendicular line mentioned, and since the weights of the parts themselves are equal, the centrifugal forces due to the rotation of the governor head cause equal turning moments about the pivots. These turning moments are opposed by spring I99 and they tend to move both weights away from the centerto a position to open the contact 19I 81.

It is clear that the balancing of the high speed inertia members I14 and I15 is effected in exactly the same manner.

The result of this balancing is that within reasonable limits which are defined by the angular displacements from the theoretical perpendicular of the line through the pivot and the center of gravity, the inertia members are perfectly balanced against vibration of the governor as a whole, and so are not affected by any movement of, or shock to, the vehicle truck on which the governor is supported.

An analysis of the parts of the form of governor head as disclosed in Figs. 1 and 2 will disclose that the inertia members are balanced against vibration of the governor as a whole in a manner similar to that just explained for the form of governor head disclosed in Figs. 9 to 12.

Although I have herein shown and described only certain forms of apparatus embodying my invention, it is' understood that various changes and modifications may be made therein within the scope of the appended claims without departing from the spirit and scope of my invention,

Having thus described my invention, what I claim is:

1. A speed responsive device comprising, a plate which is adapted to be rotated at different speeds, two inertia members pivotally mounted on the plate each at a different point some distance from the center, a contact arm and a weight arm for each member, said contact arms eifective to cooperate with each other to permit the weight arms to swing away from the center of the plate or toward the center only in unison, contact mechanism mounted on the plate and operatively connected with the contact arm of at least one of said members, restraining mechanism connected with said members and eifectitve to bias said members to operate the contact mechanism to a given position, and said restraining mechanism so proportioned that the centrifugal forces exerted by the weight arms when the plate is rotated are If now any vibrational force in any direction is set up, it acts at the effective to operate the contact mechanism away from said given position only at speeds above a predetermined speed.

2. A speed responsive device comprising, a plate which is adapted to be rotated at different speeds. two inertia members pivotally mounted on the plate each at a difierent point some distance from the center, a contact arm and a weight arm for each member, said contact arms effective to cooperate with each other to permit the weight arms 'to swing away from the center of the plate or toward the center only in unison, contact mechanism mounted on the plate and operatively connected with at least one of said members, and means including a spring the two opposite ends of which are connected with the weight arms respectively, and said spring effective to bias said members to operate the contact mechanism to a given position and to permit the centrifugal forces exerted by the weight arms when the plate is rotated to operate the contact mechanism away from said given position only at speeds above a predetermined speed.

3. A speed responsive device comprising, a plate which is adapted to be rotated at different speeds. two bell cranks mounted on the plate at points substantially an equal distance from the center and each provided with a weight arm and a contact arm, said contact arms interlocked with each other to permit the weight arms to swing away from the center of the plate or toward the center only in unison, a contact mounted on the contact arm of at least one crank, a stationary contact mounted on said plate, means including a spring the two opposite ends of which are connected with the two weight arms respectively and efl'ective to bias said cranks to a position for causing the contact on said contact arm to engage the stationary contact, and said spring and weights being so proportioned that the centrifugal forces exerted by said weights when the plate is rotated are ineffective to rotate the cranks about their pivots and operate the contact on said contact arm away from said stationary contact at all speeds below a predetermined speed.

4. A speed responsive device comprising, a plate which is adapted to be rotated at diflerent speeds, a first pair of inertia members pivotally mounted on one-half of the plate with the two members positioned on opposite sides of the center of the plate, a second pair of inertia members pivotally mounted on the other half of the plate with the two members positioned on opposite sides of the center of the plate, a contact arm and a weight arm for each of said inertia members, said contact arms of each pair formed to interlock with each other to permit the weight arms of the respective pair to swing away from the plate center or toward the center only in unison, a movable circuit controlling contact for each pair mounted on a particular one of the contact arms, two stationary circuit controlling contacts mounted on the plate, a spring for each pair of inertia members the two opposite ends of which are connected with the weight arms of the associated pair and which is effective to bias the members to a position for causing the associated movable contact to engage a particular one of the stationary contacts, and said spring and weights of each pair so proportioned that the centrifugal forces exerted by said weights when the plate is rotated are ineffective to rotate the members about their pivots and operate the movable contact away from the stationary contact at all speeds below a particular predetermined speed.

5. A speed responsive device comprising, a plate which is adapted to be rotated at different speeds. two inertia members pivotally mounted on the plate on opposite sides of the center, means elective to interlock said members to permit movement of the members about their pivots in unison only, contact mechanism mounted on the plate and operatively engaging at least one of said members, restraining means including a spring connected to both said members and effective to bias said members to operate the contact mechanism to a given position, and said parts so proportioned and adjusted that the centrifugal forces exerted by said members when the plate is rotated are eifective to operate said contact mechanism away from said given position only at speeds above a predetermined speed.

6. A speed responsive device comprising, a plate. means including a pair of gears for operatively connecting said plate with a shaft for rotation of the plate at a speed determined by the speed of the shaft, contact mechanism mounted on said plate and biased to a closed position, another contact biased to a closed position, means including an inertia member mounted on the plate and operatively connected with said contact mechanism for operating said contact mechanism away from said closed position at a predetermined speed, and manually operable means effective to disengage said gears and to open said other contact in unison.

'7. A speed responsive device comprising, a plate which is adapted to be rotated at diiferent speeds, a bell crank having a weight secured to one arm and a circuit controlling contact secured to the other arm. means for pivotally mounting said crank on said plate in a position in which the center of the weight and the center of the contact are located on diametrical lines of the plate substantially at right angles to each other, a stationary contact mounted on the plate for engaging the contact of the crank and positioned to limit rotation of the crank about its pivot in a direction to move the weight toward the center of the plate, means including a spring connected to said crank and eflective to bias the crank to the position of engagement of said contacts, said springs so proportioned that the centrifugal forces exerted by said weight when the plate is rotated are ineflective to rotate said crank about its pivot to move its contact away from said stationary contact at all speeds below a predetermined speed, and an auxiliary weight mounted on the crank opposite the contact arm and proportioned to substantially balance the forces of the contact arm.

8. A speed responsive device comprising, a plate which is adapted to be rotated at diilerent speeds, a circuit controlling contact mounted on the plate, a bell crank having a weight secured to one arm and a circuit controlling contact secured to the other arm, means for pivotally mounting said crank on said plate for movement from one position where its contact engages said plate contact to another position when saidcontacts are out of engagement in response to movement of said weight toward and away from the plate center, means including a spring effective to bias said crank to said one position, said spring so proportioned that the centrifugal forces exerted by said weight when the plate is rotated are ineffective to operate said crank away from said one position at all speeds below a predetermined speed and said spring so positioned as to exert substantially constant torque onsaid crank about its pivot in moving between said two positions, and an auxiliary weight mounted on the crank opposite the contact arm and proportioned to substantially balance the contact arm.

9. A speed responsive device comprising, a plate which is adapted to be rotated at difierent speeds, a circuit controlling contact spring mounted on said plate, an inertia member including a fiat spring one end of which is secured to a pivot arm and the other end of which has mounted thereon a weight, a circuit controlling contact secured to said flat spring, means for mounting said member on said plate for movement of the weight toward and away from the plate center, and said flat spring so proportioned and adjusted that the inertia member is biased to the position where the contact on the flat spring engages the circuit controlling contact spring and the centrifugal forces exerted by said weight when the plate is rotated are ineffective to operate said member away from said position of engagement of the contacts at all speeds below a predetermined speed.

10. A speed responsive device comprising, a plate which is adapted to be rotated at different speeds, a first pair of inertia members pivotally mounted on one-half of the plate with the two members positioned on opposite sides of the center of the plate, a second pair of inertia members pivotally mounted on the other half of the plate with the two members positioned on opposite sides of the center of the plate, interlocking means for each of said pair of inertia members effective to permit the members of the respective pair to swing away from the plate center or toward the center only in unison, two circuit controlling contact mechanisms mounted on the plate one for each pair of inertia members, and a biasing spring for each pair of inertia members each of which springs is efiective to bias the associated inertia members to a position for closing the associated contact mechanism, said springs each so proportioned and adjusted that the centrifugal forces exerted by the associated inertia members when the plate is rotated are effective to rotate the members about their pivots and operate the contact mechanism to an open position only at speeds above a predetermined speed.

11. A speed responsive device comprising a plate which is adapted to be rotated at different speeds, two bell cranks mounted on the plate at points substantially an equal distance from the center and each provided with a weight arm and a contact arm, said contact arms one formed with a forked end to fit over a straight end portion of the other whereby the weight arms are permitted to swing away from the center of the plate or toward the center in unison, a contact mounted on the outer prong of the fork, a contact mounted on a post secured in said plate for engagement with the contact on said prong, means including a spring the opposite ends of which are connected with the two weight arms respectively to bias said cranks to a position where said contacts engage, and said spring and weights so proportioned that the centrifugal forces exerted by said weights when the plate is rotated are ineflective to rotate the cranks about their pivots and the contact on the prong of said one contact arm away from the contact on the post at all speeds below a predetermined speed.

HERBERT L. BONE. 

